Validation of Under-Resolved Numerical Simulations of the PDC Exhaust Flow Based on High Speed Schlieren

Nadolski, Maikel; Haghdoost, Mohammad Rezay; Gray, Joshua; Edgington-Mitchell, Daniel; Oberleithner, Kilian; Klein, Rupert

doi:10.1007/978-3-319-98177-2_15

Cited by 5 publications

(4 citation statements)

References 15 publications

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“…Consider the series of time-resolved schlieren images of a starting jet produced by a deflagration-detonation-transition presented in Figure 30. 223,224 Here the vortex in question is the starting-vortex, rather than a typical shear layer vortex, and is thus far stronger than those observed in steady jets, which makes the Figure 29. Schematic representation of a vortex interacting with a stationary shock, based on the numerical results of Grasso and Pirozzoli.…”

Section: 22mentioning

confidence: 95%

“…Consider the series of time-resolved schlieren images of a starting jet produced by a deflagration-detonation-transition presented in Figure 30. 223,224 Here the vortex in question is the starting-vortex, rather than a typical shear layer vortex, and is thus far stronger than those observed in steady jets, which makes the phenomenon easier to visualize. The first image (half of which is replaced with a schematic representation), shows a typical triple shock formation characteristic of an underexpanded jet, but with the reflected shock terminating in the leading vortex ring.…”

Section: The Four Fundamental Mechanisms Of Resonant Self-excitationmentioning

confidence: 99%

See 1 more Smart Citation

Aeroacoustic resonance and self-excitation in screeching and impinging supersonic jets – A review

Edgington-Mitchell

2019

International Journal of Aeroacoustics

147

101

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Supersonic jets, particularly shock-containing jets, often exhibit high-intensity, discrete-frequency acoustic tones. These tones are the signature of an aeroacoustic resonance loop established by the flow. This paper considers two of the classical forms of supersonic jet resonance: screech in shock-containing free jets and tones generated by the impingement of a jet against a surface. The first half of the paper provides a historical perspective on research into both forms of resonance, ranging from the seminal works of Alan Powell to recent contributions from high-fidelity numerical simulation, experiment, and stability theory. The second half of the paper provides a critical assessment of current understanding around the four processes that characterize jet resonance: a downstream propagation of energy, an acoustic generation mechanism, an upstream propagation of energy, and a receptivity mechanism.

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Section: 22mentioning

confidence: 95%

“…Consider the series of time-resolved schlieren images of a starting jet produced by a deflagration-detonation-transition presented in Figure 30. 223,224 Here the vortex in question is the starting-vortex, rather than a typical shear layer vortex, and is thus far stronger than those observed in steady jets, which makes the phenomenon easier to visualize. The first image (half of which is replaced with a schematic representation), shows a typical triple shock formation characteristic of an underexpanded jet, but with the reflected shock terminating in the leading vortex ring.…”

Section: The Four Fundamental Mechanisms Of Resonant Self-excitationmentioning

confidence: 99%

Aeroacoustic resonance and self-excitation in screeching and impinging supersonic jets – A review

Edgington-Mitchell

2019

International Journal of Aeroacoustics

147

101

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“…These exhaust and suction phases are caused by a number of compression and expansion waves propagating inside the PDC. These results are very well suited for validation of low-dimensional numerical schemes developed for PDC development [52]. Comparing the PIV results for the partially and overfilled operating condition shows that the fill-fraction only affects the first exhaust phase in respect to the local axial velocity and global volume flux.…”

Section: Discussionmentioning

confidence: 82%

Investigation of the Exhaust Flow of a Pulse Detonation Combustor at different Operating Conditions based on High-Speed Schlieren and PIV

Haghdoost

Edgington-Mitchell²,

Paschereit

et al. 2019

AIAA Scitech 2019 Forum

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The exhaust flow of a Pulse Detonation Combustor (PDC) is investigated for different operating conditions. The PDC consists of two units, the deflagration to detonation transition section and the exhaust tube with a straight nozzle. High-speed high-resolution schlieren images visualize the shock dynamics downstream of the nozzle. The flow dynamics during one full PDC cycle is examined via high-speed Particle Image Velocimetry. A well-suited solid tracer particle for supersonic reactive flow is determined in a preliminary study to minimize the PIV measurement error. The investigated operating conditions of the PDC differ in fillfraction, which is the percentage of the tube filled with a reactive mixture. With increasing fill-fraction, the flow features grow in size and strength, as the propagation velocity of the leading shock increases. The blow down process of the PDC is characterized by several exhaust and suction phases. An increase in fill-fraction results in a stronger first exhaust phase, while the subsequent suction and exhaust phases remain almost unaffected.

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“…Artificial oscillations at discontinuities in the numerical scheme (such as the shock) are prevented by limiting the slopes of the reconstruction step using the van-Leer limiter (see Toro (2013) for further details). This numerical scheme has been presented in a number of previous works (Nadolski et al 2019;Rezay Haghdoost et al 2020a and is well validated.…”

Section: Descriptionmentioning

confidence: 99%

Diffraction of shock waves through a non-quiescent medium

et al. 2022

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An investigation of shock diffraction through a non-quiescent background medium is presented using both experimental and numerical techniques. Unlike diffracting shocks in quiescent media, a spatial distortion of the shock front occurs, producing a region of constant shock angle. An example of this process arises in the exhaust from a pulse-detonation combustor. As the background velocity is increased, such as through the inclusion of a converging nozzle at the exhaust, the spatial distortion becomes more apparent. Numerical simulations using a compressible Euler solver demonstrate that the distortion is not due to the geometrical influence of the nozzle, but rather is a function of the magnitude of the background flow velocity. The distortion is studied using a modified geometrical shock dynamics formulation which includes the background flow and is validated against experiments. A simple model is presented to predict the shock distortion angle in the weak-shock limit. Finally, the axial decay behaviour of the shock is investigated and it is shown that the advection of the shock by the background flow delays the arrival of the head and tail of the expansion characteristic at the centreline. This leads to an increase in the rate of decay of the shock Mach number as the background flow velocity is increased.

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Validation of Under-Resolved Numerical Simulations of the PDC Exhaust Flow Based on High Speed Schlieren

Cited by 5 publications

References 15 publications

Aeroacoustic resonance and self-excitation in screeching and impinging supersonic jets – A review

Aeroacoustic resonance and self-excitation in screeching and impinging supersonic jets – A review

Investigation of the Exhaust Flow of a Pulse Detonation Combustor at different Operating Conditions based on High-Speed Schlieren and PIV

Diffraction of shock waves through a non-quiescent medium

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